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| Name: | ||||||||||||||||||||||
| Miloslav Znojil | ||||||||||||||||||||||
| Reviewer number: | ||||||||||||||||||||||
| 9689 | ||||||||||||||||||||||
| Email: | ||||||||||||||||||||||
| znojil@ujf.cas.cz | ||||||||||||||||||||||
| Item's zbl-Number: | ||||||||||||||||||||||
| DE 018 217 573 | ||||||||||||||||||||||
| Author(s): | ||||||||||||||||||||||
| Arov, D. Z.: | ||||||||||||||||||||||
| Shorttitle: | ||||||||||||||||||||||
| Scattering matrix and impedance of a canonical differential system with a dissipative boundary condition | ||||||||||||||||||||||
| Source: | ||||||||||||||||||||||
| St. Petersbg. Math. J. 13, No. 4, 527-547 (2002); translation from Algebra Anal. 13, No. 4, 26-53 (2001). | ||||||||||||||||||||||
| Classification: | ||||||||||||||||||||||
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Keywords:
| Volterra operators; canonical differential system; dissipative boundary condition; rational matrix-valued friction; impedance; scattering matrix; dynamical pliability; inverse problem; string with friction; Darlington factorization; electrical chains; monodromy matrix; | Review: | The paper is devoted to a study of certain systems of linear differential equations on a finite interval (0,L). I recommend that the interested reader glimpses at eq. (5.1) first. This is the second-order equation for the amplitude of oscillations of a string with an arbitrary distribution of its mass and with a certain frequency-dependent friction r at point L (=right end of the string) and/or impedance c (i.e., the Krein's ``pliability of the velocity") at zero. At this point, the author's older study of this problem (reference [1] where r was assumed independent of frequences) emerges as the direct predecessor and guide to the present text (where r is assumed to be a rational real function of frequences). The methods and proofs (based, basically, on the Darligton's factorization approach) remain fairly similar, and the results characterize again the class of impedances by transition to the system of the two first-order equations. One is prepared to start reading the text carefully from the start and to get acquainted with the problem in its natural and sufficiently general matrix formulation. Its key ingredient is the representation of the matrix of the canonical first-order differential-equation system in question in the form of a product of a matrix square root J of the unit matrix I with a positive matrix factor H called ``Hermitian". A broad area of further applications is covered in this way in principle (e.g., c may be related to ``impedance" or ``scattering matrix" etc). Thus, the reader now reveals the meaning of the title of the paper and is prepared to endulge the wealth of the structure theorems for c in various special cases, rewarded by the final understanding of eq. (5.1) once more, being given the nice and elegant necessary and sufficient conditions for c in Theorem 5.1, a guide to the construction of the related monodromy matrix etc. Remarks to the editors: |
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